Electrical dispenser for deodorant or insecticide

ABSTRACT

In an electrical dispenser ( 10 ) for deodorant or insecticide which contains electric heating means ( 40 ) placed near the first end ( 76 A) of a wick ( 76 ) the second end ( 76 B) of which is dipped into a deodorant or insecticide liquid ( 72 ) contained in a small bottle ( 70 ), the electric heating means ( 40 ) consist of a resistive heating strip ( 40 ) wrapped around the first end ( 76 A) of the wick ( 76 ).

[0001] The present invention relates to an electrical dispenser for deodorant or insecticide of the type comprised of a casing designed to house the upper portion of a small bottle containing a deodorant or insecticide liquid. Inside the casing there is an electrical resistance electrically connected to an electric plug to be inserted in a socket supplied by the standard voltage (for example 220-230V) of an electrical system.

[0002] The electrical resistance is placed near the upper free end of a wick, the other end of which is placed inside a small bottle dipped into a deodorant or insecticide liquid. The latter, due to capillarity, raises through the wick until reaching and impregnating the upper free end of the wick.

[0003] In order to make the dispenser operative, it is necessary to insert the electric plug in a socket: thus, the supplied electrical resistance warms up, the heat generated also heats the upper free end of the wick and the deodorant or insecticide liquid contained within. The deodorant or insecticide liquid is composed of active elements dissolved into a solvent, whereby when the temperature of the wick reaches the evaporation point of the solvent, the latter evaporates releasing in the air the deodorant or the insecticide.

[0004] There are, however, different embodiments of such a device.

[0005] A first embodiment consists of a ceramic resistance or, better, a thread resistance inserted in a ceramic element, usually of a parallelepipedic shape, which protects the resistance and, at the same time, operates like a radiator. The ceramic element is placed in contact with the upper free end of the wick.

[0006] It is easy to understand that the efficiency of such a device is very far from reaching an optimal value, because only a portion of the ceramic element is near the free end of the wick and, then, a great portion of it does not contribute in heating the wick at all. Furthemore, in the case that the ceramic element should be built in a parallelepipedic shape for semplifying the construction, the thermal exchange between the electrical resistance and the free end of the wick is reduced, as well.

[0007] A second embodiment of the prior art consists of two metallic rings or washers which are overlapped by interposing a tablet or disk made of resistive material. One ring is connected to one of the two electric contacts of the plug and the other ring to the other electric contact of the plug; the free end of the wick is inserted inside the two metallic rings.

[0008] By supplying the electric plug, the two metallic rings lead the electric current to the resistive tablet or disk which warms up. Then, the heat generated by the tablet or disk passes, by thermal conduction, into the two metallic rings which heat the free end of the wick.

[0009] Although the heat is generated all around the wick, the amount of the heat trasmitted by the heating elements to the end of the wick still remains low. In fact, only a portion of the two rings is placed near the end of the wick, that is the inner cylindrical surface, whereas, a non negligible surface comprising the outer cylindrical surface, and above all, the two anular surfaces of the two metallic rings faced outwards, does not contribute to heating the end of the wick.

[0010] Furthermore, all these embodiments have some complications due to the fact that, in addition to having to construct the resistive elements (for example the metallic rings and the resistive tablet), it is necessary to build a casing designed to house all the components, to realize the electric connections in order to connect the metallic rings to the electric plug and to insert all these elements necessary for the correct functioning of the device. For example, in order to avoid that a possible overheating may irreversebly damage the dispenser, it is necessary to insert a protective element against the possible overload of current. Then, a fuse or an electric resistance of low value is inserted and able to accept only a low electrical power, so as to interrupt the current flow in the case its value increases and reaches an unacceptable level.

[0011] It is clear that, in addition, both the time of construction and assembly becomes longer, with the consequence of relevantly increasing the final cost.

[0012] The aim of the invention is to build an electrical dispenser for deodorant or insecticide which eliminates the drawbacks cited in reference to the described prior art.

[0013] In particular the dispenser must have a considerable thermal efficiency between the resistive elements and the end of the wick, thus allowing for the reduction of the dimension of the device and for limiting the intensity of the electric current, with evident advantages.

[0014] Moreover, the dispenser must be simple, both in construction and assembly phases, in particular it must be composed of only a few elements. Consequently the reliability is increased, whereas the time of construction and the final cost decrease.

[0015] The aim is reached by an electrical dispenser for deodorant or insecticide initially described, that is comprised of a casing which contains electric heating means placed near a first end of a wick, the second end of which is dipped into a deodorant or insecticide liquid contained in a small bottle, so that said first end is impregnated with a deodorant or insecticide liquid, said electric heating means being electrically connected to an electric plug, so that electrically supplying the plug said first end of said wick warms up and the deodorant or insecticide liquid contained evaporates, characterized in that said electric heating means comprise a resistive heating strip wrapped around said first end of said wick.

[0016] In so doing, a resistive element is built, i.e. the resistive heating strip, which assures a high efficiency of the thermal exchange with the first end of the wick. The wick, in fact, is completely surrounded by the strip and the strip provides, at the same time, a considerable surface of thermal exchange.

[0017] In particular the dispenser comprises two cylinders, an outer cylinder and an inner cylinder placed inside and coaxial with respect to said outer cylinder, said outer and inner cylinders define a cylindrical space inside which said resistive heating strip is inserted.

[0018] The resistive heating strip is thus protected and possible damage is avoided and, moreover, the outer cylinder operates like an insulating barrier for keeping the heat generated contained, thus increasing the thermal efficiency.

[0019] The resistive heating strip comprises a central portion made of resistive material which surrounds the first end of said wick, and two end portions made of electrically conductive material. In particular said two end portions of conductive materials have narrowed sections so as to make preferential areas of interruption of the electric current in case of overcurrents and, thus, overheating.

[0020] In this way, possible damage to the dispenser is avoided in the case the current intensity should reach a high level.

[0021] Preferably, the two end portions of conductive material are electrically connected directly to said electric plug.

[0022] Consequently, the connections and, thus also the assembly are facilitated, and there is no need to insert other elements or components like fuses and/or connecting leads.

[0023] The dispenser is thus simple, easy to construct and assemble, reliable and has a low cost.

[0024] These and other advantages will be more evident by the following detailed description of embodiments provided for an illustrative and non limitative purpose with reference to the subsequent enclosed drawings herewithin, wherein:

[0025]FIG. 1 is a schematic prospective view of a an electrical dispenser for deodorant or insecticide according to the present invention wherein a small bottle of deodorant has also been also represented;

[0026]FIG. 2 is a schematic exploded view of the dispenser of FIG. 1;

[0027]FIG. 3 is a schematic prospective view of the support means for a resistive heating strip;

[0028]FIG. 4 is a top view of the resistive heating strip;

[0029]FIGS. 5 and 6 are cross sections of FIG. 4 respectively taken along section lines V-V and VI-VI;

[0030]FIG. 7 is a top view of a resistive heating strip according to a variant of the invention;

[0031]FIG. 8 is a schematic prospective view of the support means wherein the resistive heating strip of FIG. 7 has been inserted.

[0032] In FIG. 1 an electrical dispenser for deodorant or insecticide is entirely represented with reference 10, and a small bottle 70 is also represented containg a deodorant or insecticide liquid 72.

[0033] The electrical dispenser 10 is comprised of a casing 12 wherein there is an upper opening 14, from which the evaporated deodorant or insecticide goes out, and a lower opening 18 which forms a housing seat 18 for the neck 74 of the small bottle 70. The dispenser 10 also comprises an electric plug 16 designed to be inserted in a socket supplied to the standard voltage of the electrical system, such as 220-230V.

[0034] A wick 76 is inserted in the small bottle 70 having a first end 76A which comes out from the small bottle 70 and a second end 76B which penetrates inside the small bottle 70 and is in contact with the deodorant or insecticide liquid 72.

[0035] The neck 74 of the small bottle 70 is inserted into the housing seat 18 of the dispenser 10, so that the first end 76A of the wick 76 is housed inside the dispenser 10 in the manner which will be described in the following.

[0036] From FIG. 2, it can be noted that the casing 12 is comprised of a bottom 20 and a cover 22. The housing seat 18, wherein the neck 74 of the small bottle 70 is inserted, is made in the bottom 20, whereas the upper opening 14, from which the evaporated deodorant or insecticide comes out, is made on the cover 22. An opening 24 and an opening 26 have been made respectively in the bottom 20 and in the cover 22 in order to form a seat to house the electric plug 16.

[0037] A heating device 30 is housed inside the casing 12 and is able to heat the first end 76A of the wick 76.

[0038] The heating device 30, as better illustrated in FIG. 3, is comprised of an outer cylinder 32 and an inner cylinder 34. The outer cylinder 32 is cut along a generatrix line to form a longitudinal slot 36 and its inner diameter is greater than the outer diameter of the inner cylinder 34. By inserting the inner cylinder 34 into the outer clinder 32, a cylindrical anular space 33 is created, wherein a resitive heating strip 40, represented in FIG. 4, is inserted into it.

[0039] The resistive heating strip 40 comprises three portions: a central portion 42 and two end portions 44,46. The strip 40 is composed of three overlapped layers: a support layer of insulating material 48, an intermediate layer 50,52 and, at last, an outer covering layer of insulating material 54.

[0040] More specifically, as represented respectively in FIGS. 5 and 6, in the central portion 42 of the strip 40 there is an intermediate layer of resistive material 50, whereas in the end portions 44 and 46 of the strip 40 there is an intermediate layer made up of conductive material 52.

[0041] For the intermediate layer of resistive material 50 a PTF material (polymer thick film) is used, preferably with PTC characteristics (positive coefficient temperature), so that as the temperature increases, the value of the electric resistance increases, thus limiting the possible overcurrents which may overheat and, thus, damage the dispenser.

[0042] The intermediate layer made up of conductive material 52 is made, for example, by applying a silver film, since silver is an optimum conductor of electricity.

[0043] For the support layer of insulating material 48, polyester is preferably used, as well as for the outer covering layer of insulating material 54.

[0044] The width of the resistive heating strip 40 is substantially equal to the height of the outer cylinder 32 and the inner cylinder 34. Instead, the length of the intermediate portion 42, containing the resistive layer 50, is substantially equal to the circumference of the anular space formed between the outer cylinder 32 and the inner cylinder 34 and this portion is inserted in such a way to completely wrap the inner cylinder 34. Differently, both the end portions 44,46 come out from the longitudinal slot 36 of the outer cylinder 32, as represented in FIG. 2, and their length allows for electrically connecting their free ends 44A and 46A with the electric plug 16.

[0045] In both end portions 44 and 46, the conductive material 52 is uniformly applied over the total surface of the support layer 42, except for the two areas wherein the material is applied in a manner to form two narrowings or reduced sections for the flow of electric current, respectively indicated by references 56 and 58. The narrowings 56 and 58 form two preferential areas of interruption of the electric current in the case of overcurrents, and thus of overheating.

[0046] In FIGS. 7 and 8 a variant of the invention is represented, wherein the elements already described have been indicated with the same references plus 100.

[0047] In this case, the resistive heating strip 140 comprises a central portion 142, the width of which is still substantially equal to the height of the outer cylinder 132 and the inner cylinder 134, whereas the two end portions 144,146 have a width lesser than half the height of the outer and inner cylinders 132,134. The two end portions 144,146 are oppositely arranged so as to come out tangentially with respect to the cylinders 132,134, without superimposing each other (see FIG. 8), thus avoiding any fold which might jeopardize the correct functioning of the resistive heating strip 140.

[0048] The assembly of the electrical dispenser 10 is very easy.

[0049] In fact, after having inserted the inner cylinder 34 into the outer cylinder 32 and after having inserted the resistive heating strip 40 in the anular space, designed in the way described above, it is sufficient to connect the free ends 44A,46A of the end portions 44,46 to the electric plug 16 and, at last, enclose everything by coupling the bottom 20 with the cover 22.

[0050] To operate the device, it is also necessary to insert the neck 74 of the small bottle 70 into the housing seat 18 of the dispenser 10, so that the first end 76A of the wick 76 is housed inside the cylinders 32,34 and to insert the electric plug 16 into a standard electric socket.

[0051] In such a manner, due to the “Joule effect”,the central portion 42 of the resisive heating strip 40 gets warm and, consequently, by thermal conduction, also the inner cylinder 34 and the outer cylinder 32, and then the first end 76A of the wick 76 inserted into, warms up. The temperature arrived at is sufficient for evaporating the solvent contained in the deodorant or insecticide liquid and, then, to permit for the release of the deodorant or insecticide substance dissolved therein.

[0052] It is evident that the thermal exchange between the resistive heating strip 40 and the wick 76A is significant, thus permitting the dispenser to run efficientely.

[0053] In order to facilitate the heat transmission towards the first end 76A of the wick 76, the central portion 42 of the resistive heating strip 40 is placed in strict contact with the outer surface of the inner cylinder 34; consequently, an air gap which functions as insulation is formed between the resistive heating strip 40 and the inner surface of the outer cylinder 32.

[0054] In addition, it is possible to make the outer cylinder 32 and the inner cylinder 34 of different materials: preferably the outer cylinder 32 should be made up of thermically insulating material so as to minimize, or even make negligible, the loss, namely of heat transmission outwards, whereas the inner cylinder 34 should be made up of a thermally conductive material.

[0055] From the above-said, the dispenser 10 is composed of only a few components that are easily constructed and also the assembly is simple and rapid. Therefore, the cost is reduced and the reliability is very high.

[0056] Finally, it is evident that changes or variations conceptually or functionally equivalent fall inside the scope of the present invention.

[0057] For example, the central portion made up of resitive material 42 might be wound like a helix inside the anular cylindrical space 33 formed between the outer cylinder 32 and the inner cylinder 34, so as to form various rotations.

[0058] Or, aramidic fibers might be used for the support layer of the insulating material 48 and for the outer covering layer of insulating material 54 which are very strong so as to allow a remarkable reduction of the thickness of said strip with evident advantages. 

1. Electrical dispenser for deodorant or insecticide comprising a casing (10) which contains electric heating means (40) placed near a first end (76A) of a wick (76), the second end of which (76B) is dipped into a deodorant or insecticide liquid (72) contained in a small bottle (70), so that said first end (76A) is impregnated with a deodorant or insecticide liquid (72), said electric heating means (40) being electrically connected to an electric plug (16), so that electrically supplying the plug said first end (76A) of said wick (76) warms up and the deodorant or insecticide liquid (72) contained evaporates, characterized in that said electric heating means (40) comprise a resistive heating strip (40) wrapped around said first end (76A) of said wick (76).
 2. Electrical dispenser for deodorant or insecticide according to claim 1, characterized in that it comprises support means (32,34) for said resistive heating strip (40).
 3. Electrical dispenser for deodorant or insecticide according to claim 2, characterized in that said support means consist of at least one cylinder (32,34) on which said resistive heating strip (40) is wrapped.
 4. Electrical dispenser for deodorant or insecticide according to claim 3, characterized in that said at least one cylinder are two in number, an outer cylinder (32) and an inner cylinder (34) placed inside and coaxial with respect to said outer cylinder (32), said outer cylinder (32) and inner cylinder (34) defining an anular cylindrical space (33) inside which said resistive heating strip (40) is inserted.
 5. Electrical dispenser for deodorant or insecticide according to claim 4, characterized in that said resistive heating strip (40) comprises a central portion (42) made up of a resistive material (50) inserted into said anular cylindrical space (33) and two end portions (44,46) made up of an electrically conductive material (52).
 6. Electrical dispenser for deodorant or insecticide according to claim 5, characterized in that said outer cylinder (42) has a slot (36) along a generatrix line from which said two end portions (44,46) of said resistive heating strip (40) come out.
 7. Electrical dispenser for deodorant or insecticide according to claim 6, characterized in that the two free ends (44A,46B) of said two end portions (44,46) are made up of an electrically conductive material and are electrically connected with said electric plug (16).
 8. Electrical dispenser for deodorant or insecticide according to claim 5, characterized in that said resistive material (50) and said electrically conductive material (52) are applied onto a support strip of non-conductive material (48).
 9. Electrical dispenser for deodorant or insecticide according to claim 8, characterized in that said resistive material (50) and said electrically conductive material (52) are covered by a covering strip of non-conductive material (54).
 10. Electrical dispenser for deodorant or insecticide according to claim 9, characterized in that, in said two end portions (44,46), the conductive material (52) is applied in such a way as to form at last one narrowing (56,58) for the flow of electric current so as to form a preferential area of interruption for the electric current in the case of overcurrents and, thus, overheating.
 11. Electrical dispenser for deodorant or insecticide according to claim 6, characterized in that said resistive heating strip (140) comprises two end portions (144,146) the width of which is lesser one half the width of said central portion (142) and oppositely arranged in respect to said central portion (42), so that the end portions (144,146) may tangentially come out in respect to said cylinders (132,134) without overimposing each other.
 12. Electrical dispenser for deodorant or insecticide according to, any of claims 5 to 11, characterized in that in said central portion (42), made up of resistive material (50) and inserted into said anular cylindrical space (33), is wound up forming at least one rotation around said inner cylinder (34).
 13. Electrical dispenser for deodorant or insecticide according to claim 12, characterized in that said central portion (42) forms only one rotation around said inner cylinder (34).
 14. Electrical dispenser for deodorant or insecticide according to claim 13, characterized in that said two end portions (44, 46) of the strip, from where they come out of said slot (36) of said outer cylinder (32), are folded so as to avoid any electric contact therebetween.
 15. Electrical dispenser for deodorant or insecticide according to claim 12, characterized in that said central portion (42) is wound like an helix around said inner cylinder (34) so as to form at least two rotations.
 16. Electrical dispenser for deodorant or insecticide according to any of claims 5 to 15, characterized in that said resistive material (50) is a PTF material (polymer thick film).
 17. Electrical dispenser for deodorant or insecticide according to claim 16, characterized in that said PTF resistive material (50) is a PTC material (positive coefficient temperature).
 18. Electrical dispenser for deodorant or insecticide according to any of claims 5 to 17, characterized in that said elettrically conductive material (52) is silver.
 19. Electrical dispenser for deodorant or insecticide according to any of claims 7 to 18, characterized in that said non-conductive material (48,54) is polyester or aramidic fiber. 